DE3786949T2 - Information recording and reproducing apparatus. - Google Patents

Abstract

In an information recording and reproducing apparatus using a disc-shaped information recording medium having a plurality of recording tracks, each of which recording tracks is divided into a plurality of sectors, to record and reproduce information on and from the information recording medium on a sector-by-sector basis, when a target sector (Sn) is detected to be a defective sector whose address can not be reproduced, in the first place, a reference sector (Sn-k), which is positioned preceding the defective target sector and whose address can be reproduced, is detected. Then, a rotational latency time from the detected reference sector (Sn-k) to the defective target sector (Sn) is measured by using: (l) a time measuring circuit (l3) for measuring the rotational latency time per se; or (2) a counter circuit (l4) for counting the number of a sector mark or sector marks (ll) which indicate the presence of an associated sector or sectors and which are detected during the rotational latency time, so that the defective target sector (Sn) may be taken to be a normally detected target sector whereby information may be recorded and reproduced on and from the defective target sector (Sn), thereby making it possible to perform recording and reproduction of informa tion on and from a defective sector whose address can not be reproduced.

Description

BACKGROUND OF THE INVENTION FIELD OF INVENTION

The present invention relates to an information recording and reproducing device, and more particularly, it relates to an information recording and reproducing device in which recording and reproducing of information are performed on and from a disk-shaped information recording medium having a plurality of recording tracks, each of the recording tracks being divided into a number of sectors, and the information recording and reproducing are performed on a sector-by-sector basis.

DESCRIPTION OF THE RELATED ART

In performing recording and reproducing information on and from a disk-shaped recording medium on a sector-by-sector basis, a defective sector whose address cannot be reproduced due to an error in the information recording medium, etc. is sometimes encountered. A method of recording and reproducing information on and from such a defective sector in a conventional information recording and reproducing device is described, for example, in Japanese Unexamined Patent Publication No. 59-154654. That is, when it is impossible to reproduce a track address of a target sector on and from which information is to be recorded and reproduced, but it is possible to identify only a sector address of the target sector by coincidence detection using the result of detection of the respective track addresses of n sectors arranged preceding the target sector, it is possible to identify the track address of the defective target sector and thereby perform reproduction and recording of information on and from the defective target sector even if its track address cannot be reproduced.

However, with such a conventional method, it is impossible to perform information recording and reproduction on and from a target sector if not only the track address but also the sector address of the target sector cannot be reproduced.

From JP-A-61-17271 an optical disk device for recording and reproducing information on and from a disk-shaped optical information recording medium having a plurality of recording tracks is known. Under normal circumstances, when the address area is without an error, a SYNC code detection signal is generated from a signal recorded at a leading part of the address field of a respective recording sector. synchronization pattern is reproduced, and from this SYNC code detection signal is derived a sector format control signal for controlling the reproduction of the recording sector. On the other hand, if the address range of the target sector is defective and the SYNC code detection signal cannot be reproduced in this way, a substitute signal is generated from the SYNC code detection signal of the previous sector by simply delaying it and using it to derive the sector format control signal for the defective sector. However, because the substitute signal from which the sector format control signal is obtained is obtained by delaying the SYNC code detection signal from the address field of the reference sector for the same constant period of time for all sectors, the sector format control signal for the defective sector has no relationship with the address data of the reference sector, which is a disadvantage particularly when the information recording and reproducing device uses a recording format in which the time intervals of detection of the SYNC signals are not constant for all tracks.

Furthermore, from EP-A-0 147 065 a recording and reproducing device for a disk-shaped optical recording medium having a spiral guide track and containing a single index field and a number of sectors is known. In this known device a counter is reset by an index mark signal detected from said index field and at the same time the counter counts a sector mark signal detected from the address field of each of the respective sectors. If, as a result of an error, an address of a target sector cannot be detected, the output signal of the counter is used to generate a sector control signal therefrom for carrying out recording and reproducing operations from the target sector having the erroneous address. In this known device it is necessary for correct operation that the index mark is always correctly detected to reset the counter and recording or playback cannot be performed from a destination sector with an incorrect address if the sector marks cannot be properly detected from each sector.

SUMMARY OF THE INVENTION

Therefore, it is an object of the present invention to eliminate the disadvantages of the prior art devices.

In particular, it is an object of the present invention to provide an information recording and reproducing device in which information recording and reproduction can be performed on and from a target sector even when not only the track address but also the sector address of the target sector cannot be reproduced.

According to the present invention, there is provided an information recording and reproducing device using a disk-shaped information recording medium having a plurality of recording tracks each of which is divided into a number of sectors, each of the sectors consisting of a sector identifier field containing address information and a data field for recording data so that information is recorded or reproduced on or from the sectors, the device comprising: means for detecting a sector whose address cannot be reproduced as a defective sector; means for detecting a sector whose address can be reproduced and which is located preceding a target sector on or from which information is to be recorded or reproduced as a reference sector; means for generating measurement data determining the rotational latency from the detected reference sector to the target sector; and means for measuring the rotational latency from the detected reference sector to the target sector on the basis of the Measurement data; whereby, when a target sector is detected as a defective sector, the reference sector is detected first and then the rotational latency from the detected reference sector to the defective target sector is used for recording and reproducing information on and from the defective target sector.

In the information recording and reproducing device of the present invention, when the target sector on and from which information is recorded and reproduced is detected as a defective sector whose address cannot be reproduced, a reference sector which is located preceding the target sector and whose address can be reproduced is first detected. Then, the rotation latency from the reference sector to the target sector is measured by using a time measuring circuit or by using a counter circuit for counting the number of sector marks detected from the respective sectors, thereby recording and reproducing information on and from the defective target sector whose address cannot be reproduced.

The above and other objects and features of this invention will become more apparent from the description of the embodiments of the invention given hereinafter in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a block diagram showing the structure of the information recording and reproducing device of an embodiment of the present invention;

Fig. 2 is an explanatory diagram for explaining the structure of a track;

Fig. 3 is a flow chart for explaining the operations of recording and reproducing information on and from a defective sector;

Fig. 4A and 4B are block diagrams each showing an example of the rotation latency measuring circuit 5; and

Fig. 5 is a waveform diagram showing the waveforms of signals appearing at various portions of the rotation latency measuring circuit 5 during its operation.

DESCRIPTION OF PREFERRED EMBODIMENTS

Referring to the drawings, the embodiments of the present invention will be described in more detail hereinafter. Fig. 1 is a block diagram showing the information recording and reproducing device of an embodiment of the present invention. In Fig. 1, the information recording and reproducing device of this embodiment includes a main control circuit 2 for controlling the entire information recording and reproducing device in accordance with an apparatus command signal 100 sent from a host computer, a sector detection circuit 4 for detecting address information coincident with a retrieval sector address signal 102 set by the main control circuit 2 in a reproduced signal 101 sent from a drive unit 3 and outputting a detection signal 107, a rotation latency measuring circuit 5 for measuring a rotation latency from a reference sector to a target sector on the basis of measurement data 103 sent from the main control circuit 2, an information recording circuit 6 for modulating recording information 104 supplied from the host computer 1 and supplying a recording signal 105 generated by the modulation to the drive unit 3, an information reproducing circuit 7 for Demodulation of data contained in the reproduced signal 101 sent by the drive unit 3 and supplying reproduced information 106 obtained by the demodulation to the processing computer 1, a start circuit 8 for supplying a start signal 109 to the information recording circuit 6 or the information reproducing circuit 7 in accordance with the detection signal 107 supplied from the sector detection circuit 4 or a substitute detection signal 108 supplied from the rotation latency measuring circuit 5.

Fig. 2 shows the structure of each track in an information recording medium used in this embodiment. As shown in Fig. 2(a), each track is equally divided into n sectors ranging from a sector S1 to a sector Sn, and each sector consists of a sector identifier (ID) field 9 and a data field 10. Furthermore, as shown in Fig. 2(b), the sector identifier field 9 consists of a sector mark 11 indicating the start end of a sector common to all sectors, and an address area 12 having address information including a track address and a sector address and which is unique to each sector.

According to the flow chart shown in Fig. 3, the operation of the information recording and reproducing device of the embodiment of the present invention having the above-described structure will be explained hereinafter.

(A) Upon receipt of the apparatus command signal 100 from the processing computer 1, the main control circuit 2 interprets the apparatus command signal 100 and outputs a drive command signal 110 for instructing the drive unit 3 to perform a seek operation to search for a track containing a target sector.

(B) When the drive unit 3 detects an abnormality while performing the seek operation, the main control circuit 2 receives a drive status signal 111 output from the drive unit 3 indicating abnormal termination of the seek operation, and sends a Recognition information 112 to the host computer 1 to thereby terminate the execution of the command.

(C) When the seek operation is normally completed, the drive unit 3 confirms the assigned track address and sends a drive status signal 111 indicating normal completion of the seek operation to the main control circuit 2. In order to detect a target sector on and from which information is to be recorded or reproduced, the main control circuit 2 sets a target sector address as a retrieval sector address signal 102 and sends the retrieval sector address signal 102 and an enable signal 113 to the sector detection circuit 4 and the start circuit 8, respectively.

(D) The sector detection circuit 4 detects the information contained in a reproduced signal 101 sent from the drive unit 3 and performs coincidence detection between the detected address information and the retrieval sector address signal 102. When the target sector is detected by the coincidence between the detected address information and the retrieval sector address signal 102, the sector detection circuit 4 sends a detection signal 107 to the start circuit 8.

(E) If the target sector is not detected within a maximum rotation latency, the main control circuit 2 stops sending the enable signal 113 to the start circuit 8, takes a sector on the disk immediately before the target sector as a reference sector, sets the address of the reference sector as a new retrieval sector address signal 102, and sends the new retrieval sector address signal 102 to the sector detection circuit 4.

(F) The sector detection circuit 4 detects the information contained in the reproduced signal 101 sent from the drive unit 3 and performs coincidence detection between the detected address information and the new recovery sector address signal 102.

(G) If the reference sector is not detected within the maximum rotation latency, the main control circuit 2 takes a sector on the disk immediately before the current reference sector as a new reference sector, sets the address of the new reference sector as another new retrieval sector address signal 102, and sends the another new retrieval sector address signal 102 to the sector detection circuit 4.

(H) When the sector detection circuit 4 detects the reference sector, it sends a detection signal 107 to the main control circuit 2. The main control circuit 2 sends an enable signal 113 to the start circuit 8 and at the same time sends measurement data 103 corresponding to a rotation latency from the detected reference sector to the target sector to the rotation latency measuring circuit 5 and causes the circuit 5 to start its operation. After completing the measurement of the rotation latency given by the measurement data 103, the rotation latency measuring circuit 5 considers the target sector to be detected and sends a substitute detection signal 108 to the start circuit 8 in place of a detection signal 107.

(I) Upon receiving the detection signal 107 sent from the sector detection circuit 4 in the process in the above paragraph (D) or the substitute detection signal 108 sent from the rotation latency measuring circuit 5 in the process in the above paragraph (H), the start circuit 8 outputs a start signal 109 which is sent to the information recording circuit 6 or the information reproducing circuit 7 in accordance with the content of the enable signal 113 sent from the main control circuit 2. In an information recording process, the information recording circuit 6 modulates the recording information 104 sent from the host computer 1 and sends a recording signal thus generated 105 to the drive unit 3 for recording on the disk therein, thereby completing the execution of the apparatus command 100. In an information reproduction operation, on the other hand, the information circuit 7 detects and demodulates data contained in the reproduced signal 101 sent from the drive unit 3 and sends reproduced information 106 thus generated to the host computer 1, thereby completing the execution of an apparatus command 100.

Next, with respect to the operation of rotational latency measurement performed by the rotational latency measuring circuit 5 in this embodiment, two methods thereof will be described with reference to the block diagrams of Figs. 4A and 4B and the signal waveform diagram of Fig. 5. Fig. 5(a) shows the reproduced signal 101 output from the drive unit 3 within a period of time from a reference sector Sn-k preceding a target sector Sn by k sectors to the target sector Sn. In Fig. 5(a), symbols ID and DF represent a sector identification field 9 (ID) and a data field 10 included in each sector, respectively. Fig. 5(b) shows the detection signal 107 output from the sector detection circuit 4. In Fig. 5(b), reference numeral 116 denotes a detection signal detected from the reference sector Sn-k, and reference numeral 117 denotes the timing of a detection signal to be detected from the target sector Sn when the target sector Sn is not a defective sector. Fig. 5(c) shows sector marks 11 (SM₁, SM₂, . . . , SMk-1, SMk) which are detected by being recognized in the reproduced signal 101 at the beginning end portions of the sector identification field 9 of the respective sectors ranging from the sector Sn-k+1 following the reference sector Sn-k to the target sector Sn.

A first of the two methods is to measure the rotation latency using a time measuring circuit 13 as shown in Fig. 4A. In this method, the measurement data output from the main control circuit 2 103 a rotation latency per se from the reference sector to the target sector. For example, as shown in Fig. 5 (a), when the reference sector Sn is detected k sectors preceding the target sector Sn, the measurement data 103 is given by k TS sec, where TS represents a sector time length in seconds. The rotation latency time measurement operation is started by a process such that the sector detection circuit 4 sends the detection signal 116 shown in Fig. 5(b) to the main control circuit 2 after its detection of the reference sector Sn-k, and, in response, the main control circuit 2 supplies the data of k · TS sec to the time measuring circuit 13 shown in Fig. 4A as the measurement data 103. When the operation of the time measuring circuit 13 is started by the supply of the measurement data 103 thereto, the time measuring circuit 13 measures the time indicated by the measurement data 103 using a clock signal 114 and, after completion of the time measuring operation thereof, generates a substitute detection signal 108 in place of a detection signal 117 shown by a broken line in Fig. 5(b).

In a second method, on the other hand, the rotational latency is measured by using a counter circuit 14 as shown in Fig. 4B. In this method, when a sector mark 11 shown in Fig. 5(c) format-recorded at the initial end of each sector identification field 9 (as shown in Fig. 2(b)) is detected by discrimination from the reproduced signal 101, the number of sector marks 11 detected during the rotational latency from the reference sector to the target sector is supplied to the counter circuit 14 as the measurement data 103. For example, when the reference sector Sn-k is detected sectors ahead of the target sector Sn as shown in Fig. 5(a), the total number of sector marks SMi (i = 1 to k) detected in the sector identification fields 9 of the respective sectors ranging from the sector Sn-k+1 to the target sector Sn as shown in Fig. 5(c) is supplied to the counter circuit 14 as measurement data 103. When the operation of the counter circuit 14 is stopped by supplying the data as the measurement data 103 to this is started, the counter circuit 14 counts sector marks 11 and generates a substitute detection signal 108 in place of a detection signal 117 shown by a broken line in Fig. 5(b) after completion of the counting operation thereof, only with a time delay corresponding to the rotation latency for an address area 12 of a sector identification field 9 shown in Fig. 2(b).

Furthermore, the main control circuit 2 in this embodiment can be realized by using a general-purpose microprocessor. The microprocessor can include the time measuring circuit or counter circuit explained above. Alternatively, it is possible to realize the function of the rotation latency measuring circuit 5 in the microprocessor by counting the sector marks 11 shown in Fig. 5(c) using software in the microprocessor.

As described above, in the information recording and reproducing device according to the present invention, when a target sector on and from which information is to be recorded or reproduced is detected as a defective sector whose address cannot be reproduced, a sector which is located preceding the defective target sector and whose address can be reproduced is first detected as a reference sector. Then, by measuring the rotational latency from the detected reference sector to the defective target sector using a time measuring circuit or a counter circuit for counting the number of sector marks 11 detected in the respective sectors, it is possible to effect recording and reproduction of information on and from the defective target sector as if the target sector can be detected. Accordingly, with the information recording and reproducing device according to the present invention, it is possible to record and reproduce information on and from a sector even if the sector is defective. Thus, the information recording and reproducing device has and reproducing device of the present invention has a noticeable advantage in practical use.

Claims (7)

1. Information recording and reproducing device, which uses a disk-shaped information recording medium having a plurality of recording tracks, each of which is divided into a number of sectors (S₁ to Sb), each of the sectors consisting of a sector identifier field (9) containing address information and a data field (10) for data recording, so that information is recorded and reproduced on and from the sectors, the device comprising: means (4) for detecting a sector whose address cannot be reproduced as a defective sector; means (4) for detecting a sector whose address can be reproduced and which is located preceding a target sector (Sn) on which and from which information is to be recorded or reproduced, as reference sector (Sn-k); marked by a device (2) for generating measurement data (103) determining the rotation latency time from the detected reference sector (Sn-k) to the target sector (Sn); and means (5) for measuring the rotation latency time from the detected reference sector (Sn-k) to the target sector (Sn) on the basis of the measurement data (103); whereby, when a target sector (Sn) is detected as a defective sector, first the reference sector (Sn-k) is detected and then the rotational latency from the detected reference sector (Sn-k) to the defective target sector (Sn) is used for recording and reproducing information to and from the defective target sector (Sn). 2. An information recording and reproducing device according to claim 1, wherein the rotation latency is measured using a time measuring circuit (13). 3. Information recording and reproducing device according to claim 2, wherein the time measuring circuit (13) for measuring the rotational latency time is contained in a microprocessor. 4. Information recording and reproducing device according to claim 1, wherein the sector identification field (9) includes a sector mark (11) for indicating the presence of the associated sector identification field (9), so that when the sector mark (11) is detected during the rotational latency, the rotational latency is measured using a counter circuit (14) for counting the number of the detected sector marks (11). 5. Information recording and reproducing device according to claim 4, wherein the counter circuit (14) for measuring the rotational latency time is contained in a microprocessor. 6. Information recording and reproducing device according to one of claims 1 to 5, in which only a sector is detected as the reference sector (Sn-k) whose address can be reproduced and which is arranged one or two sectors before the target sector (Sn) on the disk-shaped information recording medium. 7. Information recording and reproducing device according to one of claims 1 to 6, wherein only when a target sector (Sn) is detected as a defective sector in reproducing information, a reference sector (Sn-k) is detected and then the rotational latency from the detected reference sector (Sn-k) to the defective target sector (Sn) is measured to thereby reproduce information from the defective target sector.